Packing of the polynucleosome chain in interphase chromosomes: evidence for a contribution of crowding and entropic forces

In the crowded intranuclear environment, entropic depletion forces between macromolecules are expected to be strong. A review of simulations of linear polymers leads to several predictions about probable conformations of a polynucleosome chain in these conditions. These include a globular conformation, variable compaction due to different local rigidity or curvature of the mosaic of isochores, satellite sequences, and nucleosomes containing different histone variants, and the possibility that chromosomes represent separate phases like those seen in heterogeneous particle mixtures by experiment and simulation. Experimental results which show that macromolecular crowding alone, in the absence of exogenous cations, can stabilise interphase chromosomes and cause self-association of polynucleosome chains are presented. Together, these considerations suggest that macromolecular crowding and entropic forces are major factors in packing polynucleosome chains in vivo.     

Two types of constitutive heterochromatin in the chromosomes of some Fritillaria species

A Giemsa banding technique has been used to study C-banding in mitotic chromosomes in root tips of Fritillaria graeca, F. crassifolia and F. rhodocanakis, all diploids (2n=24) belonging to the graeca group. In the first two the C-bands were of two types, diverging in respect of staining regularly and specifically within chromosomes. In one type it was weak, being intermediate between that of intensely stained ones, representing the other class, and the euchromatin. In F. graeca the pale bands were proximally localized and confined to 5 pairs, whereas in F. crassifolia they occurred only in the 4 M chromosomes, in each within the centromeric constriction as a large inclusion. The interphase nuclei of both species contained pale and heavily stained chromocentres. No pale ones occurred in such nuclei of F. rhodocanakis. The probability is discussed that the two classes of C-band represent distinct types of heterochromatin, differing both in respect of condensation throughout the whole mitotic cycle and in the repetitive DNA sequences they most likely contain. In all 3 species pairs of Giemsa-positive centromeric dots, representing the centromeres, were masked both by proximally or centromerically localized bands, irrespective of the class of heterochromatin they represented.     

Structure and DNA methylation pattern of partially heterochromatinised endosperm nuclei in Gagea lutea (Liliaceae)

Pentaploid endosperm nuclei in certain Gagea species exhibit large masses of sticky and dense chromatin, not observed in somatic nuclei. These heterochromatin masses most probably stem from the triploid chalasal polar nucleus of the embryo sac, thus representing an example of facultative heterochromatinisation in plants. In the present investigation, we studied the nuclei in Gagea lutea (L.) Ker-Gawl. endosperm tissue. The position of the heterochromatin in interphase nuclei was observed by confocal laser scanning microscopy (CLSM) and the DNA methylation status of the euchromatin and heterochromatin was analysed by immunolabelling with an antibody raised against 5-methylcytosine (anti-5-mC). In young endosperms, heterochromatin was relatively dispersed, occupying some peripheral and inner parts of the nuclei. In a later endosperm development, the nuclei became smaller and more pycnotic, and the heterochromatin masses were placed predominantly near the nuclear periphery. The distribution of anti-5-mC labelling on the heterochromatic regions was unequal: some parts appeared hypermethylated while other parts were, like the euchromatin, not labelled. During mitosis, the labelling intensity of all the chromosomes was approximately the same, thus indicating that there are no cytologically detectable methylation differences among the individual sets of chromosomes. However, differences in the anti-5-mC signal intensity along individual chromosomes were observed, resulting in banding patterns with highly positive bands apparently representing constitutive heterochromatic regions. From these results it is obvious that facultative heterochromatinisation, in contrast to constitutive heterochromatinisation, need not be strictly accompanied by a prominent DNA hypermethylation. Received: 24 April 1997 / Accepted: 28 July 1997     

Nucleosome packing in interphase chromatin.

Higher-order chromatin fibers (200--300 A in diameter) are reproducibly released from nuclei after lysis in the absence of formalin and/or detergent. Electron microscope analysis of these fibers shows that they are composed of a continuous array of closely apposed nucleosomes which display several distinct packing patterns. Analysis of the organization of nucleosomes within these arrays and their distribution along long stretches of chromatin suggest that the basic 100-A chromatin fiber is not packed into discrete superbeads and is not folded into a uniform solenoid within the native 250-A fiber. Furthermore, because similar higher-order fibers have been visualized in metaphase chromosomes, the existence of this fiber class appears to be independent of the degree of in vivo chromatin condensation.     

Low angle x-ray diffraction studies of HeLa metaphase chromosomes: effects of histone phosphorylation and chromosome isolation procedure

To test whether gross changes in chromatin structure occur during the cell cycle, we compared HeLa mitotic metaphase chromosomes and interphase nuclei by low angle x-ray diffraction. Interphase nuclei and metaphase chromosomes differ only in the 30-40-nm packing reflection, but not in the higher angle part of the x-ray diffraction pattern. Our interpretation of these results is that the transition to metaphase affects only the packing of chromatin fibers and not, to the resolution of our method, the internal structure of nucleosomes or the pattern of nucleosome packing within chromatin fibers. In particular, phosphorylation of histones H1 and H3 at mitosis does not affect chromatin fiber structure, since the same x-ray results are obtained whether or not histone dephosphorylation is prevented by isolating metaphase chromosomes in the presence of 5,5'-dithiobis(2- nitrobenzoate) or low concentrations of p-chloromercuriphenylsulfonate (ClHgPhSO3). We also compared metaphase chromosomes isolated by several different published procedures, and found that the isolation procedure can significantly affect the x-ray diffraction pattern. High concentrations of ClHgPhSO3 can also profoundly affect the pattern.     

Biochemical and cytological studies of bleomycin actions on chromatin and chromosomes

Interaction of bleomycin with nuclei isolated from a variety of mammalian cells resulted in the release of nucleosomes. When isolated mononucleosomes (core plus linker) were re-treated with bleomycin, no further degradation of DNA occurred. The results suggest that the bleomycin cleavage sites in chromatin are present only in the linker region and that there are probably only one or two cleavage sites per linker. The repeat lengths of nucleosomal DNA released by bleomycin from nuclei of different species are different; this variability is considered to reflect the length of the linker. Incorporation of BrdU into DNA did not alter the bleomycin action on nucleosomes. When mitotic cells were held at metaphase for a prolonged period, bleomycin caused a gradual disintegration of chromosomes, although the bleomycin cleavage sites in metaphase chromosomes were found to be the same as those in interphase nuclei.     

Self-association of polynucleosome chains by macromolecular crowding

The crowding of macromolecules in the cell nucleus, where their concentration is in the range of 100 mg/ml, is predicted to result in strong entropic forces between them. Here the effects of crowding on polynucleosome chains in vitro were studied to evaluate if these forces could contribute to the packing of chromatin in the nucleus in vivo. Soluble polynucleosomes approximately 20 nucleosomes in length formed fast-sedimenting complexes in the presence of inert, volume-occupying agents poly(ethylene glycol) (PEG) or dextran. This self-association was reversible and consistent with the effect of macromolecular crowding. In the presence of these crowding agents, polynucleosomes formed large assemblies as seen by fluorescence microscopy after labelling DNA with the fluorescent stain DAPI, and formed rods and sheets at a higher concentration of crowding agent. Self-association caused by crowding does not require exogenous cations. Single, approximately 800 nucleosome-long chains prepared in 100 muM Hepes buffer with no added cations, labelled with the fluorescent DNA stain YOYO-1, and spread on a polylysine-coated surface formed compact 3-D clusters in the presence of PEG or dextran. This reversible packing of polynucleosome chains by crowding may help to understand their compact conformations in the nucleus. These results, together with the known collapse of linear polymers in crowded milieux, suggest that entropic forces due to crowding, which have not been considered previously, may be an important factor in the packing of nucleosome chains in the nucleus.     

Electron microscopic and biochemical evidence that chromatin structure is a repeating unit

Electron microscopic and biochemical studies demonstrate that the fundamental structure of chromatin depleted of lysine-rich histones is composed of a flexible chain of spherical particles (nucleosomes), about 125 Å in diameter, connected by DNA filaments. Such a chromatin preparation can be separated by centrifugation into two fractions which differ in the spacing of the nucleosomes. In one fraction almost all of the DNA is condensed in nucleosomes, while the other fraction contains long stretches of free DNA connecting regions where the nucleosomes are closely packed. The isolated nucleosomes contain about 200 base pairs of DNA and the four histones F2a₁, F2a₂, and F2b, and F3 in an overall histone/DNA ratio of 0.97. In such a structure the DNA is compacted slightly more than five times from its extended length. The same basic structure can be visualized in chromatin spilling out of lysed nuclei. However, in this latter case the nucleosomes are very closely packed, suggesting that histone F1 is involved in the superpacking of DNA in chromosomes and nuclei. The chromatin fiber appears to be a self-assembling structure, since the nucleosomal arrangement can be reconstituted in vitro from DNA and the four histones F2a₁, F2a₂, F2b and F3 only, irrespective of their cellular origin.     

Genome and chromosome structure: Twelve dynamic and evolving genomes

Chromosomes are not inert structures that haul the genome through cell division. The dynamic properties of chromosomes, during the cell cycle, the lifetime of the organism and across evolutionary time, featured prominently at the 49(th) Annual Drosophila Research Conference. Platform presentations, workshops and posters focused on many aspects of chromosome structure and function including chromosome interactions such as trans-silencing and pairing between homologous and non-homologous chromosomes, specialized portions of the chromosome including the centromere and telomeres, the structure, function and evolution of the large heterochromatic domains such as the Y and 4(th) chromosomes, centric heterochromatin and subtelomeric heterochromatin. The speed of evolutionary changes in these regions, and the consequences for speciation and hybrid-incompatibility, were recurring themes. Finally, there was considerable new insight offered into the mechanics by which chromosomes are rearranged and changes in the types of alterations occurring over the lifetime of the organism, which can result in novel genes and gene flow between chromosomes. The availability of the twelve sequenced Drosophila genomes has allowed new insights into the structure, function and evolutionary transformation of chromosomes and genomes that will continue to transform our view of the chromosome as a dynamic and flexible entity that houses and regulates the genome.     

C- and Q-chromatin of the experimentally condensed human interphase chromosomes]

Condensed interphase chromosomes of the cultured human lymphocytes obtained by the fusion of interphase and metaphase cells were studied using C- and Q-bands techniques. The appearance and localization of the constitutive heterochromatin blocks on condensed chromosomes at G1-period were the same as on the metaphase ones. These characters were used for a group and individual identification of some chromosomes condensed at G1-period and for a study of the association of the constitutive heterochromatin blocks in the interphase nuclei. The fluorescent analysis of the chromosomes condensed at G1-period detected some bright fluorescent blocks of the constitutive heterochromatin.     

Spatial organization of chromosomes in the salivary gland nuclei of Drosophila melanogaster

Using a computer-based system for model building and analysis, three-dimensional models of 24 Drosophila melanogaster salivary gland nuclei have been constructed from optically or physically sectioned glands, allowing several generalizations about chromosome folding and packaging in these nuclei. First and most surprising, the prominent coiling of the chromosomes is strongly chiral, with right-handed gyres predominating. Second, high frequency appositions between certain loci and the nuclear envelope appear almost exclusively at positions of intercalary heterochromatin; in addition, the chromocenter is always apposed to the envelope. Third, chromosomes are invariably separated into mutually exclusive spatial domains while usually extending across the nucleus in a polarized (Rabl) orientation. Fourth, the arms of each autosome are almost always juxtaposed, but no other relative arm positions are strongly favored. Finally, despite these nonrandom structural features, each chromosome is found to fold into a wide variety of different configurations. In addition, a set of nuclei has been analyzed in which the normally aggregrated centromeric regions of the chromosomes are located far apart from one another. These nuclei have the same architectural motifs seen in normal nuclei. This implies that such characteristics as separate chromosome domains and specific chromosome-nuclear envelope contacts are largely independent of the relative placement of the different chromosomes within the nucleus.     

Interphase chromosome arrangement in Arabidopsis thaliana is similar in differentiated and meristematic tissues and shows a transient mirror symmetry after nuclear division

Whole-mount fluorescence in situ hybridization (FISH) was applied to Arabidopsis thaliana seedlings to determine the three-dimensional (3D) interphase chromosome territory (CT) arrangement and heterochromatin location within the positional context of entire tissues or in particular cell types of morphologically well-preserved seedlings. The interphase chromosome arrangement was found to be similar between all inspected meristematic and differentiated root and shoot cells, indicating a lack of a gross reorganization during differentiation. The predominantly random CT arrangement (except for a more frequent association of the homologous chromosomes bearing a nucleolus organizer) and the peripheric location of centromeric heterochromatin were as previously observed for flow-sorted nuclei, but centromeres tend to fuse more often in nonendoreduplicating cells and NORs in differentiated cells. After mitosis, sister nuclei revealed a symmetric arrangement of homologous CTs waning with the progress of the cell cycle or in the course of differentiation. Thus, the interphase chromosome arrangement in A. thaliana nuclei seems to be constrained mainly by morphological features such as nuclear shape, presence or absence of a nucleolus organizer on chromosomes, nucleolar volume, and/or endopolyploidy level.     

Characterization of rDNAs and tandem repeats in the heterochromatin of Brassica rapa

We describe the morphology and molecular organization of heterochromatin domains in the interphase nuclei, and mitotic and meiotic chromosomes, of Brassica rapa, using DAPI staining and fluorescence in situ hybridization (FISH) of rDNA and pericentromere tandem repeats. We have developed a simple method to distinguish the centromeric regions of mitotic metaphase chromosomes by prolonged irradiation with UV light at the DAPI excitation wavelength. Application of this bleached DAPI band (BDB) karyotyping method to the 45S and 5S rDNAs and 176 bp centromere satellite repeats distinguished the 10 B. rapa chromosomes. We further characterized the centromeric repeat sequences in BAC end sequences. These fell into two classes, CentBr1 and CentBr2, occupying the centromeres of eight and two chromosomes, respectively. The centromere satellites encompassed about 30% of the total chromosomes, particularly in the core centromere blocks of all the chromosomes. Interestingly, centromere length was inversely correlated with chromosome length. The morphology and molecular organization of heterochromatin domains in interphase nuclei, and in mitotic and meiotic chromosomes, were further characterized by DAPI staining and FISH of rDNA and CentBr. The DAPI fluorescence of interphase nuclei revealed ten to twenty conspicuous chromocenters, each composed of the heterochromatin of up to four chromosomes and/or nucleolar organizing regions.     

Chromosome organization and chromatin modification: influence on genome function and evolution

Histone modifications of nucleosomes distinguish euchromatic from heterochromatic chromatin states, distinguish gene regulation in eukaryotes from that of prokaryotes, and appear to allow eukaryotes to focus recombination events on regions of highest gene concentrations. Four additional epigenetic mechanisms that regulate commitment of cell lineages to their differentiated states are involved in the inheritance of differentiated states, e.g., DNA methylation, RNA interference, gene repositioning between interphase compartments, and gene replication time. The number of additional mechanisms used increases with the taxon's somatic complexity. The ability of siRNA transcribed from one locus to target, in trans, RNAi-associated nucleation of heterochromatin in distal, but complementary, loci seems central to orchestration of chromatin states along chromosomes. Most genes are inactive when heterochromatic. However, genes within beta-heterochromatin actually require the heterochromatic state for their activity, a property that uniquely positions such genes as sources of siRNA to target heterochromatinization of both the source locus and distal loci. Vertebrate chromosomes are organized into permanent structures that, during S-phase, regulate simultaneous firing of replicon clusters. The late replicating clusters, seen as G-bands during metaphase and as meiotic chromomeres during meiosis, epitomize an ontological utilization of all five self-reinforcing epigenetic mechanisms to regulate the reversible chromatin state called facultative (conditional) heterochromatin. Alternating euchromatin/heterochromatin domains separated by band boundaries, and interphase repositioning of G-band genes during ontological commitment can impose constraints on both meiotic interactions and mammalian karyotype evolution.     

Hoechst 33258 fluorescent staining of Drosophila chromosomes

Metaphase chromosomes of D. melanogaster, D. virilis and D. eopydei were sequentilly stained with quinacrine, 33258 Hoechst and Giemsa and photographed after each step. Hoechst stained chromosomes fluoresced much brighter and with different banding patterns than quinacrine stained ones. In contrast to mammalian chromosomes, Drosophia's quinacrine and Hoechst bright bands are all in centric heterochromatin and the banding patterns seem more taxonomically divergent than external morphological characteristics. Hoechst stained D. melanogaster chromosomes show unprecedented longitudinal differentiation by the heterochromatic regions; each arm of each autosome can be unambiguously identified and the Y shows eleven bright bands. The Hoechst stained Y can also be identified in polytene chromocenters. Centric alpha heterochromatin of each D. virilis autosome is composed of two blocks which can be differtiated by a combination of quinacrine and Hoechst staining. The distal block is always Q-H- while the proximal block is, for the various autosomes, either Q-H-, Q+H- or Q+H+. With these permutations of Hoechst and quinacrine staining, D. virilis autosomes can be unambiguously distinguished. The X and two autosomes have H+ heterochromatin which can easily be seen in polytene and interphase nuclei where it seems to aggregate and exclude H- heterochromatin. This affinity of fluorochrome similar heterochromatin was been seen in colcemide induced multiple somatic non-disjunctions where H+ chromosomes were distributed to one rosette and H- chromosomes were distributed to another. Knowing the base composition and base sequences of Drosophila satellites, we conclude that AT richness may be necessary but is certainly an insufficient requirement for quinacrine bright chromatin while GC richness may be a sufficient requirement for the absence of quinacrine or Hoechst brightness. Condensed euchromatin is almost as bright as Q+ heterochromatin. While chromatin condensation has little effect on Hoechst staining, it appears to be "the most important factor responsible for quinacrine brightness.' All existing data from D. virilis indicate that each fluorochrome distinct block of alpha heterochromatin may contain a single a single DNA molecule which is one heptanucleotide repeated two million times.     

Ultrastructural organization of heterochromatin within sea urchin sperm nuclei

Chromatin within swollen or lysed isolated sperm nuclei of the sea urchin, Strongylocentrotus purpuratus, was examined by electron microscopy. Spread preparations of lysed sperm nuclei demonstrated dense aggregates of nondispersed material and beaded filaments radiating from these aggregates. These beaded fibers are similar in size and appearance to the “beads-on-a-string” seen as characteristic of chromatin spreads from numerous interphase nuclei. The beads are nucleosomes that have an average diameter of 130 Å. The interconnecting string is 40 Å indiameter and corresponds to the spacer DNA. In thin sections of swollen nuclei the sperm chromatin appears to be composed of 400 Å superbeads that are closely apposed to form 400 Å fibers. As the chromatin disperses, the superbeads are seen to be attached to one another by chromatin fibers of 110 Å diameter. In thin sections, the 400 Å superbeads appear to disperse directly into the 110 Å fibers with no intervening structures. This work demonstrates that the heterochromatin in Strongylocentrotus purpuratus sperm nuclei is composed of nucleosomes that form 100 Å filaments that are compacted into 400 Å superbeads. The superbeads coalesce to give the morphological appearance of 400 Å fibers.     

Heterochromatin and rDNA sites distribution in the holocentric chromosomes of Cuscuta approximata Bab. (Convolvulaceae).

Cuscuta is a widely distributed genus of holoparasitic plants. Holocentric chromosomes have been reported only in species of one of its subgenera (Cuscuta subg. Cuscuta). In this work, a representative of this subgenus, Cuscuta approximata, was investigated looking for its mitotic and meiotic chromosome behaviour and the heterochromatin distribution. The mitotic chromosomes showed neither primary constriction nor Rabl orientation whereas the meiotic ones exhibited the typical quadripartite structure characteristic of holocentrics, supporting the assumption of holocentric chromosomes as a synapomorphy of Cuscuta subg. Cuscuta. Chromosomes and interphase nuclei displayed many heterochromatic blocks that stained deeply with hematoxylin, 4',6-diamidino-2-phenylindole (DAPI), or after C banding. The banded karyotype showed terminal or subterminal bands in all chromosomes and central bands in some of them. The single pair of 45S rDNA sites was observed at the end of the largest chromosome pair, close to a DAPI band and a 5S rDNA site. Two other 5S rDNA site pairs were found, both closely associated with DAPI bands. The noteworthy giant nuclei of glandular cells of petals and ovary wall exhibited large chromocentres typical of polytenic nuclei. The chromosomal location of heterochromatin and rDNA sites and the structure of the endoreplicated nuclei of C. approximata seemed to be similar to those known in monocentric nuclei, suggesting that centromeric organization has little or no effect on chromatin organization.     

The inheritance of histone modifications depends upon the location in the chromosome in Saccharomyces cerevisiae

Histone modifications are important epigenetic features of chromatin that must be replicated faithfully. However, the molecular mechanisms required to duplicate and maintain histone modification patterns in chromatin remain to be determined. Here, we show that the introduction of histone modifications into newly deposited nucleosomes depends upon their location in the chromosome. In Saccharomyces cerevisiae, newly deposited nucleosomes consisting of newly synthesized histone H3-H4 tetramers are distributed throughout the entire chromosome. Methylation of lysine 4 on histone H3 (H3-K4), a hallmark of euchromatin, is introduced into these newly deposited nucleosomes, regardless of whether the neighboring preexisting nucleosomes harbor the K4 mutation in histone H3. Furthermore, if the heterochromatin-binding protein Sir3 is unavailable during DNA replication, histone H3-K4 methylation is introduced onto newly deposited nucleosomes in telomeric heterochromatin. Thus, a conservative distribution model most accurately explains the inheritance of histone modifications because the location of histones within euchromatin or heterochromatin determines which histone modifications are introduced.     

AN ANALYSIS OF HETEROCHROMATIN IN MAIZE ROOT TIPS

The B chromosomes of maize are condensed in appearance during interphase and are relatively inert genetically; therefore they fulfill the definition of heterochromatin. This heterochromatin was studied in root meristem cells by radioautography following administration of tritiated thymidine and cytidine, and was found to behave in a characteristic way, i.e. it showed asynchronous DNA synthesis and very low, if any, RNA synthesis. A cytochemical comparison of normal maize nuclei with nuclei from isogenic maize stock containing approximately 15–20 B-chromosomes in addition to the normal complement has revealed the following: (a) the DNA and histone contents are greater in nuclei with B chromosomes; (b) the proportion of DNA to histone is identical with that of nuclei containing only normal chromosomes; (c) the amount of nonhistone protein in proportion to DNA in interphase is less in nuclei with B chromosomes than in normal nuclei. In condensed B chromosomes the ratio of nonhistone protein to DNA is similar to that in other condensed chromatin, such as metaphase chromosomes and degenerating nuclei. The B chromosomes appear to have no effect on nucleolar RNA and protein. Replication of B chromosomes is precisely controlled and is comparable to that of the ordinary chromosomes not only in synthesis for mitosis but also in formation of polyploid nuclei of root cap and protoxylem cells.